/**
 ****************************************************************************************
 *
 * @file tipc_task.c
 *
 * @brief Time Profile Client Task implementation.
 *
 * Copyright (C) RivieraWaves 2009-2012
 *
 * $Rev: $
 *
 ****************************************************************************************
 */


/**
 ****************************************************************************************
 * @addtogroup TIPCTASK
 * @{
 ****************************************************************************************
 */

/*
 * INCLUDE FILES
 ****************************************************************************************
 */

#include "app_config.h"

#if (BLE_TIP_CLIENT)
#include "gap.h"
#include "attm.h"
#include "tipc.h"
#include "tipc_task.h"
#include "gatt_task.h"

/*
 * TYPE DEFINITIONS
 ****************************************************************************************
 */



/*
 * DEFINES
 ****************************************************************************************
 */

/// State machine used to retrieve Current Time service characteristics information
const struct prf_char_def tipc_cts_char[TIPC_CHAR_CTS_MAX] =
{
    /// Current Time
    [TIPC_CHAR_CTS_CURR_TIME]        = {ATT_CHAR_CT_TIME,
                                        ATT_MANDATORY,
                                        ATT_CHAR_PROP_RD|ATT_CHAR_PROP_NTF},
    /// Local Time Info
    [TIPC_CHAR_CTS_LOCAL_TIME_INFO]  = {ATT_CHAR_LOCAL_TIME_INFO,
                                        ATT_OPTIONAL,
                                        ATT_CHAR_PROP_RD},
    /// Reference Time Info
    [TIPC_CHAR_CTS_REF_TIME_INFO]    = {ATT_CHAR_REFERENCE_TIME_INFO,
                                        ATT_OPTIONAL,
                                        ATT_CHAR_PROP_RD},
};

/// State machine used to retrieve Current Time service characteristic description information
const struct prf_char_desc_def tipc_cts_char_desc[TIPC_DESC_CTS_MAX] =
{
    /// Current Time client config
    [TIPC_DESC_CTS_CURR_TIME_CLI_CFG] = {ATT_DESC_CLIENT_CHAR_CFG,
                                         ATT_MANDATORY,
                                         TIPC_CHAR_CTS_CURR_TIME},
};

/// State machine used to retrieve Next DST Change service characteristics information
const struct prf_char_def tipc_ndcs_char[TIPC_CHAR_NDCS_MAX] =
{
    /// Current Time
    [TIPC_CHAR_NDCS_TIME_WITH_DST]    = {ATT_CHAR_TIME_WITH_DST,
                                         ATT_MANDATORY,
                                         ATT_CHAR_PROP_RD},
};

/// State machine used to retrieve Reference Time Update service characteristics information
const struct prf_char_def tipc_rtus_char[TIPC_CHAR_RTUS_MAX] =
{
    /// Time Update Control Point
    [TIPC_CHAR_RTUS_TIME_UPD_CTNL_PT]    = {ATT_CHAR_TIME_UPDATE_CNTL_POINT,
                                            ATT_MANDATORY,
                                            ATT_CHAR_PROP_WR_NO_RESP},
    /// Time Update State
    [TIPC_CHAR_RTUS_TIME_UPD_STATE]      = {ATT_CHAR_TIME_UPDATE_STATE,
                                            ATT_MANDATORY,
                                            ATT_CHAR_PROP_RD},
};


/*
 * LOCAL FUNCTIONS DEFINITIONS
 ****************************************************************************************
 */

/**
 ****************************************************************************************
 * @brief Handles reception of the @ref TIPC_ENABLE_REQ message.
 * The handler enables the Time Profile Client Role.
 * @param[in] msgid Id of the message received (probably unused).
 * @param[in] param Pointer to the parameters of the message.
 * @param[in] dest_id ID of the receiving task instance (probably unused).
 * @param[in] src_id ID of the sending task instance.
 * @return If the message was consumed or not.
 ****************************************************************************************
 */
static int tipc_enable_req_handler(ke_msg_id_t const msgid,
                                   struct tipc_enable_req const *param,
                                   ke_task_id_t const dest_id,
                                   ke_task_id_t const src_id)
{
    // Status
    uint8_t status;
    // Time Profile Client Role Task Environment
    struct tipc_env_tag *tipc_env;
    // Connection Information
    struct prf_con_info con_info;

    // Fill the Connection Information structure
    con_info.conhdl = param->conhdl;
    con_info.prf_id = dest_id;
    con_info.appid  = src_id;

    // Add an environment for the provided device
    status = PRF_CLIENT_ENABLE(con_info, param, tipc);

    if (status == PRF_ERR_FEATURE_NOT_SUPPORTED)
    {
        // The message has been forwarded to another task id.
        return (KE_MSG_NO_FREE);
    }
    else if (status == PRF_ERR_OK)
    {
        tipc_env = PRF_CLIENT_GET_ENV(dest_id, tipc);

        //config connection, start discovering
        if(param->con_type == PRF_CON_DISCOVERY)
        {
            //start discovering CTS on peer
            prf_disc_svc_send(&(tipc_env->con_info), ATT_SVC_CURRENT_TIME);

            tipc_env->last_uuid_req = ATT_SVC_CURRENT_TIME;
            tipc_env->last_svc_req  = ATT_SVC_CURRENT_TIME;

            // Go to DISCOVERING state
            ke_state_set(dest_id, TIPC_DISCOVERING);
        }
        //normal connection, get saved att details
        else
        {
            tipc_env->cts = param->cts;
            tipc_env->ndcs = param->ndcs;
            tipc_env->rtus = param->rtus;

            //send APP confirmation that can start normal connection
            tipc_enable_cfm_send(tipc_env, &con_info, PRF_ERR_OK);
        }
    }
    else
    {
        // Send confirmation that can start normal connection
        tipc_enable_cfm_send(NULL, &con_info, status);
    }

    return (KE_MSG_CONSUMED);
}

/**
 ****************************************************************************************
 * @brief Handles reception of the @ref TIPC_RD_CHAR_REQ message.
 * Check if the handle exists in profile(already discovered) and send request, otherwise
 * error to APP.
 * @param[in] msgid Id of the message received (probably unused).
 * @param[in] param Pointer to the parameters of the message.
 * @param[in] dest_id ID of the receiving task instance (probably unused).
 * @param[in] src_id ID of the sending task instance.
 * @return If the message was consumed or not.
 ****************************************************************************************
 */
static int tipc_rd_char_req_handler(ke_msg_id_t const msgid,
                                        struct tipc_rd_char_req const *param,
                                        ke_task_id_t const dest_id,
                                        ke_task_id_t const src_id)
{
    // Attribute Handle
    uint16_t search_hdl = ATT_INVALID_SEARCH_HANDLE;
    // Service
    struct prf_svc *svc;

    // Get the address of the environment
    struct tipc_env_tag *tipc_env = PRF_CLIENT_GET_ENV(dest_id, tipc);

    if(param->conhdl == tipc_env->con_info.conhdl)
    {
        //Next DST Change Service Characteristic
        if (((param->char_code & TIPC_CHAR_NDCS_MASK) == TIPC_CHAR_NDCS_MASK) &&
            ((param->char_code & ~TIPC_CHAR_NDCS_MASK) < TIPC_CHAR_NDCS_MAX))
        {
            svc = &tipc_env->ndcs.svc;
            search_hdl = tipc_env->ndcs.chars[param->char_code & ~TIPC_CHAR_NDCS_MASK].val_hdl;
        }
        //Reference Time Update Service Characteristic
        else if (((param->char_code & TIPC_CHAR_RTUS_MASK) == TIPC_CHAR_RTUS_MASK) &&
                 ((param->char_code & ~TIPC_CHAR_RTUS_MASK) < TIPC_CHAR_RTUS_MAX))
        {
            svc = &tipc_env->rtus.svc;
            search_hdl = tipc_env->rtus.chars[param->char_code & ~TIPC_CHAR_RTUS_MASK].val_hdl;
        }
        else
        {
            svc = &tipc_env->cts.svc;

            //Current Time Characteristic Descriptor
            if (((param->char_code & TIPC_DESC_CTS_MASK) == TIPC_DESC_CTS_MASK) &&
                ((param->char_code & ~TIPC_DESC_CTS_MASK) < TIPC_DESC_CTS_MAX))
            {
                search_hdl = tipc_env->cts.descs[param->char_code & ~TIPC_DESC_CTS_MASK].desc_hdl;
            }
            //Current Time Service Characteristic
            else if (param->char_code < TIPC_CHAR_CTS_MAX)
            {
                search_hdl = tipc_env->cts.chars[param->char_code].val_hdl;
            }
        }

        // Check if handle is viable
        if (search_hdl != ATT_INVALID_SEARCH_HANDLE)
        {
            tipc_env->last_char_code = param->char_code;
            prf_read_char_send(&(tipc_env->con_info), svc->shdl, svc->ehdl, search_hdl);
        }
        else
        {
            tipc_error_ind_send(tipc_env, PRF_ERR_INEXISTENT_HDL);
        }
    }
    else
    {
        tipc_error_ind_send(tipc_env, PRF_ERR_INVALID_PARAM);
    }

    return (KE_MSG_CONSUMED);
}

/**
 ****************************************************************************************
 * @brief Handles reception of the @ref TIPC_CT_NTF_CFG_REQ message.
 * It allows configuration of the peer ind/ntf/stop characteristic for a specified characteristic.
 * Will return an error code if that cfg char does not exist.
 * @param[in] msgid Id of the message received (probably unused).
 * @param[in] param Pointer to the parameters of the message.
 * @param[in] dest_id ID of the receiving task instance (probably unused).
 * @param[in] src_id ID of the sending task instance.
 * @return If the message was consumed or not.
 ****************************************************************************************
 */
static int tipc_ct_ntf_cfg_req_handler(ke_msg_id_t const msgid,
                                       struct tipc_ct_ntf_cfg_req const *param,
                                       ke_task_id_t const dest_id,
                                       ke_task_id_t const src_id)
{
    uint16_t cfg_hdl = 0x0000;
    // Get the address of the environment
    struct tipc_env_tag *tipc_env = PRF_CLIENT_GET_ENV(dest_id, tipc);

    if(param->conhdl == tipc_env->con_info.conhdl)
    {
        cfg_hdl = tipc_env->cts.descs[TIPC_DESC_CTS_CURR_TIME_CLI_CFG].desc_hdl;

        //Only NTF
        if(!((param->cfg_val == PRF_CLI_STOP_NTFIND)||(param->cfg_val == PRF_CLI_START_NTF)))
        {
            tipc_error_ind_send(tipc_env, PRF_ERR_INVALID_PARAM);
        }
        else
        {
            //check if the handle value exists
            if (cfg_hdl != ATT_INVALID_SEARCH_HANDLE)
            {
                // Send GATT Write Request
                prf_gatt_write_ntf_ind(&tipc_env->con_info, cfg_hdl, param->cfg_val);
            }
            else
            {
                tipc_error_ind_send(tipc_env, PRF_ERR_INEXISTENT_HDL);
            }
        }
    }
    else
    {
        tipc_error_ind_send(tipc_env, PRF_ERR_INVALID_PARAM);
    }

    return (KE_MSG_CONSUMED);
}

/**
 ****************************************************************************************
 * @brief Handles reception of the @ref TIPC_WR_TIME_UPD_CTNL_PT_REQ message.
 * Check if the handle exists in profile(already discovered) and send request, otherwise
 * error to APP.
 * @param[in] msgid Id of the message received (probably unused).
 * @param[in] param Pointer to the parameters of the message.
 * @param[in] dest_id ID of the receiving task instance (probably unused).
 * @param[in] src_id ID of the sending task instance.
 * @return If the message was consumed or not.
 ****************************************************************************************
 */
static int tipc_wr_time_upd_ctnl_pt_req_handler(ke_msg_id_t const msgid,
                                                struct tipc_wr_time_udp_ctnl_pt_req const *param,
                                                ke_task_id_t const dest_id,
                                                ke_task_id_t const src_id)
{
    // Get the address of the environment
    struct tipc_env_tag *tipc_env = PRF_CLIENT_GET_ENV(dest_id, tipc);

    if(param->conhdl == tipc_env->con_info.conhdl)
    {
        if (tipc_env->cts.chars[TIPC_CHAR_RTUS_TIME_UPD_CTNL_PT].char_hdl != ATT_INVALID_SEARCH_HANDLE)
        {
            // Send GATT Write Request
            prf_gatt_write(&tipc_env->con_info, tipc_env->rtus.chars[TIPC_CHAR_RTUS_TIME_UPD_CTNL_PT].val_hdl,
                           (uint8_t *)&param->value, sizeof(uint8_t), GATT_WRITE_NO_RESPONSE);
        }
        //send app error indication for inexistent handle for this characteristic
        else
        {
            tipc_error_ind_send(tipc_env, PRF_ERR_INEXISTENT_HDL);
        }
    }
    else
    {
        tipc_error_ind_send(tipc_env, PRF_ERR_INVALID_PARAM);
    }

    return (KE_MSG_CONSUMED);
}

/**
 ****************************************************************************************
 * @brief Handles reception of the @ref GATT_DISC_SVC_BY_UUID_CMP_EVT message.
 * The handler stores the found service details for service discovery.
 * @param[in] msgid Id of the message received (probably unused).
 * @param[in] param Pointer to the parameters of the message.
 * @param[in] dest_id ID of the receiving task instance (probably unused).
 * @param[in] src_id ID of the sending task instance.
 * @return If the message was consumed or not.
 ****************************************************************************************
 */
static int gatt_disc_svc_by_uuid_evt_handler(ke_msg_id_t const msgid,
                                             struct gatt_disc_svc_by_uuid_cmp_evt const *param,
                                             ke_task_id_t const dest_id,
                                             ke_task_id_t const src_id)
{
    // Get the address of the environment
    struct tipc_env_tag *tipc_env = PRF_CLIENT_GET_ENV(dest_id, tipc);

    if (param->status == CO_ERROR_NO_ERROR)
    {
        //even if we get multiple responses we only store 1 range
        if (tipc_env->last_uuid_req == ATT_SVC_CURRENT_TIME)
        {
            tipc_env->cts.svc.shdl = param->list[0].start_hdl;
            tipc_env->cts.svc.ehdl = param->list[0].end_hdl;
            tipc_env->nb_svc++;
        }
        //should have just one range for this service - use first one only
        else if (tipc_env->last_uuid_req == ATT_SVC_NEXT_DST_CHANGE)
        {
            tipc_env->ndcs.svc.shdl = param->list[0].start_hdl;
            tipc_env->ndcs.svc.ehdl = param->list[0].end_hdl;
            tipc_env->nb_svc++;
        }
        //should have just one range for this service - use first one only
        else if (tipc_env->last_uuid_req == ATT_SVC_REF_TIME_UPDATE)
        {
            tipc_env->rtus.svc.shdl = param->list[0].start_hdl;
            tipc_env->rtus.svc.ehdl = param->list[0].end_hdl;
            tipc_env->nb_svc++;
        }
    }

    return (KE_MSG_CONSUMED);
}

/**
 ****************************************************************************************
 * @brief Handles reception of the @ref GATT_DISC_CHAR_ALL_CMP_EVT message.
 * Characteristics for the currently desired service handle range are obtained and kept.
 * @param[in] msgid Id of the message received (probably unused).
 * @param[in] param Pointer to the parameters of the message.
 * @param[in] dest_id ID of the receiving task instance (probably unused).
 * @param[in] src_id ID of the sending task instance.
 * @return If the message was consumed or not.
 ****************************************************************************************
 */
static int gatt_disc_char_all_evt_handler(ke_msg_id_t const msgid,
                                          struct gatt_disc_char_all_cmp_evt const *param,
                                          ke_task_id_t const dest_id,
                                          ke_task_id_t const src_id)
{
    // Get the address of the environment
    struct tipc_env_tag *tipc_env = PRF_CLIENT_GET_ENV(dest_id, tipc);

    if (param->status == CO_ERROR_NO_ERROR)
    {
        if(tipc_env->last_svc_req == ATT_SVC_CURRENT_TIME)
        {
            // Retrieve CTS characteristics
            prf_search_chars(tipc_env->cts.svc.ehdl, TIPC_CHAR_CTS_MAX,
                             &tipc_env->cts.chars[0], &tipc_cts_char[0],
                             param, &tipc_env->last_char_code);
        }
        else if(tipc_env->last_svc_req == ATT_SVC_NEXT_DST_CHANGE)
        {
            // Retrieve NDCS characteristics
            prf_search_chars(tipc_env->ndcs.svc.ehdl, TIPC_CHAR_NDCS_MAX,
                             &tipc_env->ndcs.chars[0], &tipc_ndcs_char[0],
                             param, &tipc_env->last_char_code);
        }
        else if(tipc_env->last_svc_req == ATT_SVC_REF_TIME_UPDATE)
        {
            // Retrieve RTUS characteristics
            prf_search_chars(tipc_env->rtus.svc.ehdl, TIPC_CHAR_RTUS_MAX,
                             &tipc_env->rtus.chars[0], &tipc_rtus_char[0],
                             param, &tipc_env->last_char_code);
        }
    }

    return (KE_MSG_CONSUMED);
}

/**
 ****************************************************************************************
 * @brief Handles reception of the @ref GATT_DISC_CHAR_DESC_CMP_EVT message.
 * This event can be received several times
 * @param[in] msgid Id of the message received (probably unused).
 * @param[in] param Pointer to the parameters of the message.
 * @param[in] dest_id ID of the receiving task instance (probably unused).
 * @param[in] src_id ID of the sending task instance.
 * @return If the message was consumed or not.
 ****************************************************************************************
 */
static int gatt_disc_char_desc_evt_handler(ke_msg_id_t const msgid,
                                           struct gatt_disc_char_desc_cmp_evt const *param,
                                           ke_task_id_t const dest_id,
                                           ke_task_id_t const src_id)
{
    // Get the address of the environment
    struct tipc_env_tag *tipc_env = PRF_CLIENT_GET_ENV(dest_id, tipc);

    // Retrieve CTS descriptors
    prf_search_descs(TIPC_DESC_CTS_MAX, &tipc_env->cts.descs[0], &tipc_cts_char_desc[0],
                     param, tipc_env->last_char_code);

    return (KE_MSG_CONSUMED);
}

/**
 ****************************************************************************************
 * @brief Handles reception of the @ref GATT_CMP_EVT message.
 * This generic event is received for different requests, so need to keep track.
 * @param[in] msgid Id of the message received (probably unused).
 * @param[in] param Pointer to the parameters of the message.
 * @param[in] dest_id ID of the receiving task instance (probably unused).
 * @param[in] src_id ID of the sending task instance.
 * @return If the message was consumed or not.
 ****************************************************************************************
 */
static int gatt_cmp_evt_handler(ke_msg_id_t const msgid,
                                struct gatt_cmp_evt const *param,
                                ke_task_id_t const dest_id,
                                ke_task_id_t const src_id)
{
    uint8_t status;
    // Get the address of the environment
    struct tipc_env_tag *tipc_env = PRF_CLIENT_GET_ENV(dest_id, tipc);

    if ((param->status == ATT_ERR_ATTRIBUTE_NOT_FOUND)||
        (param->status == ATT_ERR_NO_ERROR))
    {
        // Currently Discovering Current Time service characteristics.
        if(tipc_env->last_svc_req  == ATT_SVC_CURRENT_TIME)
        {
            // service start/end handles has been received
            if(tipc_env->last_uuid_req == ATT_SVC_CURRENT_TIME)
            {
                // check if service handles are not ok
                if (tipc_env->cts.svc.shdl == ATT_INVALID_HANDLE)
                {
                    // stop discovery procedure.
                    tipc_enable_cfm_send(tipc_env, &tipc_env->con_info, PRF_ERR_STOP_DISC_CHAR_MISSING);
                }
                //too many services found only one such service should exist
                else if(tipc_env->nb_svc != 1)
                {
                    // stop discovery procedure.
                    tipc_enable_cfm_send(tipc_env, &tipc_env->con_info, PRF_ERR_MULTIPLE_SVC);
                }
                // check if service handles are ok
                else
                {
                    //discover all CTS characteristics
                    prf_disc_char_all_send(&(tipc_env->con_info), &(tipc_env->cts.svc));
                    tipc_env->last_uuid_req = ATT_DECL_CHARACTERISTIC;
                }

            }
            else if(tipc_env->last_uuid_req == ATT_DECL_CHARACTERISTIC)
            {
                status = prf_check_svc_char_validity(TIPC_CHAR_CTS_MAX, tipc_env->cts.chars,
                                                     tipc_cts_char);

                //  check for characteristic properties.
                if(status == PRF_ERR_OK)
                {
                    tipc_env->last_uuid_req = ATT_INVALID_HANDLE;
                    tipc_env->last_char_code = TIPC_CHAR_CTS_CURR_TIME;
                    //request all service characteristic description for CTS
                    prf_disc_char_desc_send(&(tipc_env->con_info), &(tipc_env->cts.chars[TIPC_CHAR_CTS_CURR_TIME]));
                }
                else
                {
                    // stop discovery procedure.
                    tipc_enable_cfm_send(tipc_env, &tipc_env->con_info, status);
                }
            }
            else
            {
                status = prf_check_svc_char_desc_validity(TIPC_DESC_CTS_MAX,
                                                          tipc_env->cts.descs,
                                                          tipc_cts_char_desc,
                                                          tipc_env->cts.chars);

                if(status == PRF_ERR_OK)
                {
                    // reset number of services
                    tipc_env->nb_svc = 0;

                    //start discovering NDCS on peer
                    prf_disc_svc_send(&(tipc_env->con_info), ATT_SVC_NEXT_DST_CHANGE);

                    tipc_env->last_uuid_req = ATT_SVC_NEXT_DST_CHANGE;
                    tipc_env->last_svc_req  = ATT_SVC_NEXT_DST_CHANGE;
                }
                else
                {
                    // stop discovery procedure.
                    tipc_enable_cfm_send(tipc_env, &tipc_env->con_info, status);
                }
            }
        }

        // Currently Next DST Change service characteristics.
        else if(tipc_env->last_svc_req  == ATT_SVC_NEXT_DST_CHANGE)
        {
            // service start/end handles has been received
            if(tipc_env->last_uuid_req == ATT_SVC_NEXT_DST_CHANGE)
            {
                if (tipc_env->ndcs.svc.shdl == ATT_INVALID_HANDLE)
                {
                    // reset number of services
                    tipc_env->nb_svc = 0;

                    //start discovering RTUS on peer
                    prf_disc_svc_send(&(tipc_env->con_info), ATT_SVC_REF_TIME_UPDATE);

                    tipc_env->last_uuid_req = ATT_SVC_REF_TIME_UPDATE;
                    tipc_env->last_svc_req  = ATT_SVC_REF_TIME_UPDATE;
                }
                //too many services found only one such service should exist
                else if(tipc_env->nb_svc != 1)
                {
                    // stop discovery procedure.
                    tipc_enable_cfm_send(tipc_env, &tipc_env->con_info, PRF_ERR_MULTIPLE_SVC);
                }
                // check if service handles are ok
                else
                {
                    //discover all NDCS characteristics
                    prf_disc_char_all_send(&(tipc_env->con_info), &(tipc_env->ndcs.svc));
                    tipc_env->last_uuid_req = ATT_DECL_CHARACTERISTIC;
                }
            }
            else if(tipc_env->last_uuid_req == ATT_DECL_CHARACTERISTIC)
            {
                status = prf_check_svc_char_validity(TIPC_CHAR_NDCS_MAX, tipc_env->ndcs.chars,
                                                                         tipc_ndcs_char);

                //  check for characteristic properties.
                if(status == PRF_ERR_OK)
                {
                    // reset number of services
                    tipc_env->nb_svc = 0;

                    //start discovering RTUS on peer
                    prf_disc_svc_send(&(tipc_env->con_info), ATT_SVC_REF_TIME_UPDATE);

                    tipc_env->last_uuid_req = ATT_SVC_REF_TIME_UPDATE;
                    tipc_env->last_svc_req  = ATT_SVC_REF_TIME_UPDATE;
                }
                else
                {
                    // stop discovery procedure.
                    tipc_enable_cfm_send(tipc_env, &tipc_env->con_info, status);
                }
            }
        }

        // Currently Reference Time Update service characteristics.
        else if(tipc_env->last_svc_req  == ATT_SVC_REF_TIME_UPDATE)
        {
            // service start/end handles has been received
            if(tipc_env->last_uuid_req == ATT_SVC_REF_TIME_UPDATE)
            {
                if (tipc_env->rtus.svc.shdl == ATT_INVALID_HANDLE)
                {
                    // send app the details about the discovered TIPS DB to save
                    tipc_enable_cfm_send(tipc_env, &tipc_env->con_info, PRF_ERR_OK);
                }
                //too many services found only one such service should exist
                else if(tipc_env->nb_svc != 1)
                {
                    // stop discovery procedure.
                    tipc_enable_cfm_send(tipc_env, &tipc_env->con_info, PRF_ERR_MULTIPLE_SVC);
                }
                // check if service handles are ok
                else
                {
                    //discover all RTUS characteristics
                    prf_disc_char_all_send(&(tipc_env->con_info), &(tipc_env->rtus.svc));
                    tipc_env->last_uuid_req = ATT_DECL_CHARACTERISTIC;
                }
            }
            else if(tipc_env->last_uuid_req == ATT_DECL_CHARACTERISTIC)
            {
                status = prf_check_svc_char_validity(TIPC_CHAR_RTUS_MAX, tipc_env->rtus.chars,
                                                     tipc_rtus_char);

                //  check for characteristic properties.
                if(status == PRF_ERR_OK)
                {
                    // send app the details about the discovered TIPS DB to save
                    tipc_enable_cfm_send(tipc_env, &tipc_env->con_info, PRF_ERR_OK);
                }
                else
                {
                    // stop discovery procedure.
                    tipc_enable_cfm_send(tipc_env, &tipc_env->con_info, status);
                }
            }
        }
    }
    return (KE_MSG_CONSUMED);
}

/**
 ****************************************************************************************
 * @brief Handles reception of the @ref GATT_READ_CHAR_RESP message.
 * Generic event received after every simple read command sent to peer server.
 * @param[in] msgid Id of the message received (probably unused).
 * @param[in] param Pointer to the parameters of the message.
 * @param[in] dest_id ID of the receiving task instance (probably unused).
 * @param[in] src_id ID of the sending task instance.
 * @return If the message was consumed or not.
 ****************************************************************************************
 */
static int gatt_rd_char_rsp_handler(ke_msg_id_t const msgid,
                                    struct gatt_read_char_resp const *param,
                                    ke_task_id_t const dest_id,
                                    ke_task_id_t const src_id)
{
    // Get the address of the environment
    struct tipc_env_tag *tipc_env = PRF_CLIENT_GET_ENV(dest_id, tipc);

    if (param->status == PRF_ERR_OK)
    {
        //Current Time Characteristic
        if (tipc_env->last_char_code == TIPC_RD_CTS_CURR_TIME)
        {
            //Build a TIPC_CT_IND message
            struct tipc_ct_ind * ind = KE_MSG_ALLOC(TIPC_CT_IND,
                                                    tipc_env->con_info.appid, dest_id,
                                                    tipc_ct_ind);

            // retrieve connection handle
            ind->conhdl = tipc_env->con_info.conhdl;
            // Unpack Current Time Value.
            tipc_unpack_curr_time_value(&(ind->ct_val), (uint8_t*) param->data.data);
            //Indication Type
            ind->ind_type = TIP_RD_RSP,

            ke_msg_send(ind);
        }
        //Local Time Information Characteristic
        else if (tipc_env->last_char_code == TIPC_RD_CTS_LOCAL_TIME_INFO)
        {
            //Build a TIPC_LTI_RD_RSP message
            struct tipc_lti_rd_rsp * rsp = KE_MSG_ALLOC(TIPC_LTI_RD_RSP,
                                                        tipc_env->con_info.appid, dest_id,
                                                        tipc_lti_rd_rsp);

            // Retrieve Connection handle
            rsp->conhdl = tipc_env->con_info.conhdl;
            // Local Time Information Value
            rsp->lti_val.time_zone         = param->data.data[0];
            rsp->lti_val.dst_offset         = param->data.data[1];

            ke_msg_send(rsp);
        }
        //Reference Time Information Characteristic
        else if (tipc_env->last_char_code == TIPC_RD_CTS_REF_TIME_INFO)
        {
            //Build a TIPC_RTI_RD_RSP message
            struct tipc_rti_rd_rsp * rsp = KE_MSG_ALLOC(TIPC_RTI_RD_RSP,
                                                        tipc_env->con_info.appid, dest_id,
                                                        tipc_rti_rd_rsp);

            // Retrieve Connection handle
            rsp->conhdl = tipc_env->con_info.conhdl;
            // Reference Time Information Value
            rsp->rti_val.time_source         = param->data.data[0];
            rsp->rti_val.time_accuracy    = param->data.data[1];
            rsp->rti_val.days_update                    = param->data.data[2];
            rsp->rti_val.hours_update                    = param->data.data[3];

            ke_msg_send(rsp);
        }
        //Time with DST Characteristic
        else if (tipc_env->last_char_code == TIPC_RD_NDCS_TIME_WITH_DST)
        {
            //Build a TIPC_TDST_RD_RSP message
            struct tipc_tdst_rd_rsp * rsp = KE_MSG_ALLOC(TIPC_TDST_RD_RSP,
                                                         tipc_env->con_info.appid, dest_id,
                                                         tipc_tdst_rd_rsp);

            // Retrieve Connection handle
            rsp->conhdl = tipc_env->con_info.conhdl;
            // Time with DST Value
            prf_unpack_date_time((uint8_t*) &(param->data.data[0]), &(rsp->tdst_val.date_time));
            rsp->tdst_val.dst_offset        = param->data.data[7];

            ke_msg_send(rsp);
        }
        //Time Update State Characteristic
        else if (tipc_env->last_char_code == TIPC_RD_RTUS_TIME_UPD_STATE)
        {
            //Build a TIPC_TUS_RD_RSP message
            struct tipc_tus_rd_rsp * rsp = KE_MSG_ALLOC(TIPC_TUS_RD_RSP,
                                                        tipc_env->con_info.appid, dest_id,
                                                        tipc_tus_rd_rsp);

            // Retrieve Connection handle
            rsp->conhdl = tipc_env->con_info.conhdl;
            // Reference Time Information Value
            rsp->tus_val.current_state     = param->data.data[0];
            rsp->tus_val.result         = param->data.data[1];

            ke_msg_send(rsp);
        }
        //Current Time Characteristic - Client Characteristic Configuration Descriptor
        else if (tipc_env->last_char_code == TIPC_RD_CTS_CURR_TIME_CLI_CFG)
        {
            //Build a TIPC_CT_NTF_CFG_RD_RSP message
            struct tipc_ct_ntf_cfg_rd_rsp * rsp = KE_MSG_ALLOC(TIPC_CT_NTF_CFG_RD_RSP,
                                                               tipc_env->con_info.appid, dest_id,
                                                               tipc_ct_ntf_cfg_rd_rsp);

            // Retrieve Connection handle
            rsp->conhdl = tipc_env->con_info.conhdl;
            // Notification Configuration
            memcpy(&rsp->ntf_cfg, &param->data.data[0], sizeof(rsp->ntf_cfg));

            ke_msg_send(rsp);
        }
    }
    else
    {
        tipc_error_ind_send(tipc_env, param->status);
    }

    return (KE_MSG_CONSUMED);
}

/**
 ****************************************************************************************
 * @brief Handles reception of the @ref GATT_WRITE_CHAR_RESP message.
 * Generic event received after every simple write command sent to peer server.
 * @param[in] msgid Id of the message received (probably unused).
 * @param[in] param Pointer to the parameters of the message.
 * @param[in] dest_id ID of the receiving task instance (probably unused).
 * @param[in] src_id ID of the sending task instance.
 * @return If the message was consumed or not.
 ****************************************************************************************
 */
static int gatt_write_char_rsp_handler(ke_msg_id_t const msgid,
                                       struct gatt_write_char_resp const *param,
                                       ke_task_id_t const dest_id,
                                       ke_task_id_t const src_id)
{
    // Get the address of the environment
    struct tipc_env_tag *tipc_env = PRF_CLIENT_GET_ENV(dest_id, tipc);

    struct tipc_wr_char_rsp *wr_cfm = KE_MSG_ALLOC(TIPC_WR_CHAR_RSP,
                                                   tipc_env->con_info.appid, dest_id,
                                                   tipc_wr_char_rsp);

    wr_cfm->conhdl    = tipc_env->con_info.conhdl;
    //it will be a GATT status code
    wr_cfm->status    = param->status;
    // send the message
    ke_msg_send(wr_cfm);

    return (KE_MSG_CONSUMED);
}

/**
 ****************************************************************************************
 * @brief Handles reception of the @ref GATT_HANDLE_VALUE_NTF message.
 * @param[in] msgid Id of the message received (probably unused).
 * @param[in] param Pointer to the parameters of the message.
 * @param[in] dest_id ID of the receiving task instance (probably unused).
 * @param[in] src_id ID of the sending task instance.
 * @return If the message was consumed or not.
 ****************************************************************************************
 */
static int gatt_handle_value_ntf_handler(ke_msg_id_t const msgid,
                                        struct gatt_handle_value_notif const *param,
                                        ke_task_id_t const dest_id,
                                        ke_task_id_t const src_id)
{
    // Get the address of the environment
    struct tipc_env_tag *tipc_env = PRF_CLIENT_GET_ENV(dest_id, tipc);

    if(param->conhdl == tipc_env->con_info.conhdl)
    {
        if(param->charhdl == tipc_env->cts.chars[TIPC_CHAR_CTS_CURR_TIME].val_hdl)
        {
            //Build a TIPC_CT_IND message
            struct tipc_ct_ind * ind = KE_MSG_ALLOC(TIPC_CT_IND,
                                                    tipc_env->con_info.appid, dest_id,
                                                    tipc_ct_ind);
            // retrieve connection handle
            ind->conhdl = tipc_env->con_info.conhdl;

            // Unpack Current Time Value.
            tipc_unpack_curr_time_value(&(ind->ct_val), (uint8_t*) param->value);

            // Indication Type
            ind->ind_type = TIP_NTF;

            ke_msg_send(ind);
        }
    }
    return (KE_MSG_CONSUMED);
}

/**
 ****************************************************************************************
 * @brief Disconnection indication to TIPC.
 * @param[in] msgid     Id of the message received.
 * @param[in] param     Pointer to the parameters of the message.
 * @param[in] dest_id   ID of the receiving task instance
 * @param[in] src_id    ID of the sending task instance.
 * @return If the message was consumed or not.
 ****************************************************************************************
 */
static int gap_discon_cmp_evt_handler(ke_msg_id_t const msgid,
                                        struct gap_discon_cmp_evt const *param,
                                        ke_task_id_t const dest_id,
                                        ke_task_id_t const src_id)
{
    PRF_CLIENT_DISABLE_IND_SEND(tipc_envs, dest_id, TIPC);

    // Message is consumed
    return (KE_MSG_CONSUMED);
}

/*
 * GLOBAL VARIABLE DEFINITIONS
 ****************************************************************************************
 */

// Specifies the message handlers for the connected state
const struct ke_msg_handler tipc_connected[] =
{
    {TIPC_RD_CHAR_REQ,                  (ke_msg_func_t)tipc_rd_char_req_handler},
    {TIPC_CT_NTF_CFG_REQ,               (ke_msg_func_t)tipc_ct_ntf_cfg_req_handler},
    {TIPC_WR_TIME_UPD_CTNL_PT_REQ,      (ke_msg_func_t)tipc_wr_time_upd_ctnl_pt_req_handler},
    {GATT_READ_CHAR_RESP,               (ke_msg_func_t)gatt_rd_char_rsp_handler},
    {GATT_WRITE_CHAR_RESP,              (ke_msg_func_t)gatt_write_char_rsp_handler},
    {GATT_HANDLE_VALUE_NOTIF,           (ke_msg_func_t)gatt_handle_value_ntf_handler},
};

/// Specifies the Discovering state message handlers
const struct ke_msg_handler tipc_discovering[] =
{
    {GATT_DISC_SVC_BY_UUID_CMP_EVT, (ke_msg_func_t)gatt_disc_svc_by_uuid_evt_handler},
    {GATT_DISC_CHAR_ALL_CMP_EVT,    (ke_msg_func_t)gatt_disc_char_all_evt_handler},
    {GATT_DISC_CHAR_DESC_CMP_EVT,   (ke_msg_func_t)gatt_disc_char_desc_evt_handler},
    {GATT_CMP_EVT,                  (ke_msg_func_t)gatt_cmp_evt_handler},
};

/// Default State handlers definition
const struct ke_msg_handler tipc_default_state[] =
{
    {TIPC_ENABLE_REQ,        (ke_msg_func_t)tipc_enable_req_handler},
    {GAP_DISCON_CMP_EVT,         (ke_msg_func_t)gap_discon_cmp_evt_handler},
};

// Specifies the message handler structure for every input state.
const struct ke_state_handler tipc_state_handler[TIPC_STATE_MAX] =
{
    [TIPC_IDLE]        = KE_STATE_HANDLER_NONE,
    [TIPC_CONNECTED]   = KE_STATE_HANDLER(tipc_connected),
    [TIPC_DISCOVERING] = KE_STATE_HANDLER(tipc_discovering),
};

// Specifies the message handlers that are common to all states.
const struct ke_state_handler tipc_default_handler = KE_STATE_HANDLER(tipc_default_state);

// Defines the place holder for the states of all the task instances.
ke_state_t tipc_state[TIPC_IDX_MAX];

// Registet TIPC task into kernel
void task_tipc_desc_register(void)
{
    struct ke_task_desc task_tipc_desc;
    
    task_tipc_desc.state_handler = tipc_state_handler;
    task_tipc_desc.default_handler=&tipc_default_handler;
    task_tipc_desc.state = tipc_state;
    task_tipc_desc.state_max = TIPC_STATE_MAX;
    task_tipc_desc.idx_max = TIPC_IDX_MAX;
    
    task_desc_register(TASK_TIPC, task_tipc_desc);
}

#endif /* (BLE_TIP_CLIENT) */
/// @} TIPCTASK
